- Research article
- Open Access
Molecular evolution of the cytochrome c oxidase subunit 5 A gene in primates
- Monica Uddin†1,
- Juan C Opazo†1, 2,
- Derek E Wildman1, 3, 4,
- Chet C Sherwood5,
- Patrick R Hof6,
- Morris Goodman1, 7 and
- Lawrence I Grossman1Email author
© Uddin et al; licensee BioMed Central Ltd. 2008
- Received: 10 May 2007
- Accepted: 15 January 2008
- Published: 15 January 2008
Many electron transport chain (ETC) genes show accelerated rates of nonsynonymous nucleotide substitutions in anthropoid primate lineages, yet in non-anthropoid lineages the ETC proteins are typically highly conserved. Here, we test the hypothesis that COX5A, the ETC gene that encodes cytochrome c oxidase subunit 5A, shows a pattern of anthropoid-specific adaptive evolution, and investigate the distribution of this protein in catarrhine brains.
In a dataset comprising 29 vertebrate taxa, including representatives from all major groups of primates, there is nearly 100% conservation of the COX5A amino acid sequence among extant, non-anthropoid placental mammals. The most recent common ancestor of these species lived about 100 million years (MY) ago. In contrast, anthropoid primates show markedly elevated rates of nonsynonymous evolution. In particular, branch site tests identify five positively selected codons in anthropoids, and ancestral reconstructions infer that substitutions in these codons occurred predominantly on stem lineages (anthropoid, ape and New World monkey) and on the human terminal branch. Examination of catarrhine brain samples by immunohistochemistry characterizes for the first time COX5A protein distribution in the primate neocortex, and suggests that the protein is most abundant in the mitochondria of large-size projection neurons. Real time quantitative PCR supports previous microarray results showing COX5A is expressed in cerebral cortical tissue at a higher level in human than in chimpanzee or gorilla.
Taken together, these results suggest that both protein structural and gene regulatory changes contributed to COX5A evolution during humankind's ancestry. Furthermore, these findings are consistent with the hypothesis that adaptations in ETC genes contributed to the emergence of the energetically expensive anthropoid neocortex.
- Glial Fibrillary Acidic Protein
- Amino Acid Change
- Last Common Ancestor
- Anthropoid Primate
- Ancestral Reconstruction
The electron transport chain (ETC) genes encode essential components of the mitochondrial machinery that carries out aerobic energy production. Since the integrity of this machinery must be maintained to sustain life, the mammalian ETC proteins are generally evolutionarily conserved. Among primates, however, the ETC genes show marked upsurges in the rate of nonsynonymous (amino-acid changing) substitutions [1–17]. These upsurges, indicative of adaptive evolution, have not occurred randomly; rather, they have occurred within anthropoid primates , a clade that includes New and Old World monkeys and apes, including humans. Life history and morphological features characteristic of this clade include a relatively enlarged cerebral cortex, prolonged intrauterine fetal development followed postnatally by prolonged dependency of the young on nurturing adults, and longer lifespan. The aerobic demand of these features makes it plausible that they have acted as selective pressures during anthropoid evolution, producing adaptive amino acid and possibly regulatory changes in aerobic energy producing ETC genes.
Previous work suggested that among ETC genes, COX5A, the nuclear gene encoding cytochrome c oxidase subunit 5A, may provide a striking example of adaptive evolution. Initial characterization of subunit 5A in human revealed a high degree of conservation with the corresponding subunit in cow . In a subsequent bioinformatics study, Schmidt et al.  found that, among COX5A protein (COX5Ap) sequences from mammals, the human orthologue (the only primate representative in that dataset) differed by five amino acid residues from mouse, rat, cow and pig, all of which had identical amino acid sequences. Here, with newly generated COX5A coding region nucleotide sequences and bioinformatically extracted orthologues from publicly available whole genome sequences, we tested whether this ETC gene shows the pattern of anthropoid-specific adaptive evolution observed in 14 other ETC proteins [9, 10]. We did so within the context of a robust statistical framework, employing the PAML package  to determine: 1) whether the anthropoid clade has a different ratio of nonsynonymous/synonymous substitution rates (i.e., omega value) when compared to other placental mammals and 2) whether particular sites in COX5Ap show the signature of positive selection within the anthropoid clade.
In addition to these sequence-based analyses, we investigated patterns of COX5A expression and localization in catarrhine brains using immunohistochemistry and quantitative real time PCR (qRT-PCR) techniques. Finally, we identified the anthropoid lineages on which changes in COX5Ap residues that interact with other cytochrome c oxidase (COX) subunits occurred. Based on these results, we explored the hypothesis that COX5A evolution in humankind's ancestry involved both protein structural and gene regulatory changes, and that the anthropoid-specific evolution observed in ETC proteins represents an adaptive response to the increased energy demands of an enlarged neocortex.
Evidence for adaptive evolution
Parameter estimates and likelihood values under branch and branch-site models.
Positively selected sites
ω all branches = 0.048
ω placental mammals = 0.054; background = 0.04
ω anthropoid = 0.431; ω other placentals = 0.008; ω background = 0.042
ω estimated independently for each branch (see Fig. 1)
p0 = 0.90; p1 = 0.012; p(2a+2b) = 0.085; ω0 = 0.021; ω1 = 1; background ω2a = 0.021; ω2b = 1; foreground, ω2a = ω2b = 4.61
5 (1.00); 38 (0.99); 41 (0.53); 64 (1.00); 70 (0.97)
Model A (omega fixed)
p0 = 0.80; p1 = 0.011; p(2a+2b) = 0.192; ω0 = 0.02; ω1 = 1; background ω2a = 0.02; ω2b = 1; foreground, ω2a = ω2b = 1
Despite this elevated ratio in anthropoids, we note that the overall ratio is still less than one. This result, however, is based on the assumption that all codons are under the same selective pressure and thus share the same underlying omega value. Because this assumption is "grossly unrealistic" , and because important changes in function can result from a few key amino acid changes that do not elevate the overall omega ratio above one , we conducted a branch-site test of adaptive evolution. Here, the Anthropoidea as a total group was fixed as the foreground lineage, i.e., the branches on which there was permitted a class of sites with an omega > 1. Results from this test provide evidence of positive selection on particular sites during anthropoid evolution: the model allowing a class of sites with an omega higher than one (i.e., positive selection) fit the data significantly better than an alternative model that fixed omega at one for this same site class (p < 0.002). Specifically, five sites were identified as positively selected, four of which had a posterior probability > 0.95 (Table 1). Furthermore, we note that despite the many amino acid replacements inferred to have occurred throughout the Anthropoidea (see below), the five positively selected sites show changes occurring predominantly on stem lineages (anthropoid, ape, and New World monkey) and on the human terminal branch. The localization of these particular sites to these three stem lineages, combined with the M1 analysis (Fig. 1) depicting a classic sequence  of markedly increased dN relative to dS, followed by descendant lineages with a markedly decreased dN relative to dS, presents a pattern strongly indicative of positive selection.
Ancestral state reconstruction methods confirm and extend results obtained by the codeml analysis. Among the five sites identified as positively selected by the branch site test, four were inferred to have changed on more than one anthropoid lineage, and three were inferred to have changed on the anthropoid stem (Fig. 2). In addition, all three ancestral state reconstruction methods inferred a fourth amino acid change on the anthropoid stem that was not identified by the branch site test: a methionine to isoleucine at residue 33. It is tempting to speculate that this replacement may have acted as a "permissive" change that then allowed the selection of the other three amino acid changes occurring on this and perhaps other descendant anthropoid branch(es). This sequence of events was recently demonstrated in an elegant study by Ortlund et al.  in their investigation of cortisol-sensitive glucocorticoid receptor (GR) evolution in vertebrates. Using a combination of structural, phylogenetic and functional analyses of ancestral corticosteroid receptors, the authors identified a small set of permissive amino acid changes that stabilized specific elements of the protein. In conjunction with additional changes that diminished the receptor's sensitivity to aldosterone and increased its sensitivity to cortisol, these permissive changes allowed an additional and subsequent set of function-switching amino acid changes that conferred a fully GR-like phenotype that is sensitive only to cortisol. With respect to COX5Ap, verification of this hypothesis in future studies would require additional, fine-tuned functional data regarding the effects of each of the observed replacements alone and in concert on the activity of the reconstructed protein.
Expression and localization of COX5A
These results suggest that COX5Ap is most abundant in the mitochondria of large-size projection neurons of the neocortex. It is noteworthy that neocortical enlargement in primates is associated with increasing numbers of large pyramidal neurons that are intensely neurofilament H protein-immunoreactive, have long-range projecting axons, and are presumably metabolically costly . To understand more completely the functional role of COX5A in neocortical circuits and the possible consequences of positive selection on this gene, it will be necessary to define further the phenotype and distribution of cells in the brain that show high levels of expression for COX5Ap using strategies such as laser microcapture dissection combined with qRT-PCR or mass spectroscopy proteomics in future studies.
Role of accelerated COX evolution
As we have demonstrated, changes in COX5Ap are rare among placental mammals outside the primate clade. Among four positively selected sites identified by the branch site test with posterior probabilities > 0.95, two showed changes in their physicochemical properties: residue 5, which changed from positively charged to neutral on the ape and New World monkey stems and on the baboon terminal (Fig. 2); and residue 64, which changed from nonpolar to polar in the anthropoid stem and from polar to nonpolar on the human terminal. Interestingly, the charge neutralizations are parallel to those observed at the binding site for cytochrome c on COX in anthropoids, where the binding site changes reduced the electrostatic interaction between the docked molecules . Of note, one amino acid change on the human terminal at position 70 (Ala to Val) is a reversal of a change on the anthropoid stem (Fig. 2).
Inferred amino acid replacements in COX2p and COX4p that occur in proximity to positively selected sites in COX5Ap among anthropoid primate stem lineages.
5 (H to Q)
52 (H to N)
(H to S)
New World monkey stem
54 (S to N)
55 (T to I)
56 (M to T)
56 (T to S)
Large-bodied ape stem
57 (D to N)
New World monkey stem
38 (G to T)
52 (H to N)
54 (S to N)
55 (T to I)
22 (Y to H)
56 (M to T)
56 (T to S)
Large-bodied ape stem
41 (L to M)
52 (H to N)
54 (S to N)
64 (A to T)
63 (Q to K)
70 (V to A)
22 (Y to H)
An additional consequence of the location of COX5Ap in close contact to the nucleotide-binding domain of COX4p is potential regulation by 3,5-diiodothyronine (T2), a thyroid hormone produced when the iodothyronine deiodinase D3 acts over thyroxine (T4) . T2 has biological activity stimulating mitochondrial respiration by nuclear independent pathways [30, 31] and is known to bind to COX5Ap and abolish the allosteric inhibition of respiration at high ATP/ADP ratios . More generally, triiodothyronine (T3) thyroid hormone is considered to be a major regulator of mitochondrial activity  and has been shown to regulate the expression of a number of COX subunits, inducing functional increases in COX enzyme activity . COX5A amino acid evolution may thus represent the product of selective pressures acting on the regulation of metabolism. In the context of this hypothesis, we note that thyroid hormones are known to play a critical role in early brain development [35–37] and that humans show evidence for a greater affinity of transthyretin and/or thyroxine-binding globulin for thyroid hormone when compared to chimpanzees . Thus, it is plausible that the interaction of thyroid hormones with COX5Ap and other COX subunits may affect both the regulation of metabolism and the growth and development of important organ systems.
We have shown that COX5A has been subject to protein structural evolutionary changes in anthropoid primates and that these changes have likely been accompanied by additional gene regulatory changes affecting COX5A expression levels. Furthermore, we have suggested that these changes could affect aerobic energy metabolism among members of this group, in part because COX5Ap is a target of the thyroid hormone T2 . In addition, a recent analysis of cellular scaling in the neocortex of anthropoids showed that elevated glia-neuron ratios correlate with brain enlargement , pointing to the role of glia in providing metabolic support to neurons requiring greater energy consumption for function. Because the anthropoid amino acid changes are located in the mitochondrial matrix, close to coevolving sites in subunits 2 and 4 (Table 2) proposed to have a COX regulatory function , the COX5Ap amino acid replacements observed in this study may have promoted better energy regulation in an increasingly high demand environment. While alternative interpretations of the data are possible – that, for instance, the higher rate of nonsynonymous substitutions in COX5A in anthropoids may be a function of their larger body and smaller presumed effective population size , which would reduce the effectiveness of purifying selection on slightly deleterious amino acid replacements ; or that the changed composition of mtDNA in anthropoids  may be the "motor" driving the putative positive selection of nuclear-encoded ETC , we note that COX5Ap amino acid sequences are identical in mammals with a wide range of body sizes and basal metabolic rates (e.g., shrew, cow), and that, within the context of intergenomic interactions between nuclear- and mitochondrially encoded ETC genes, it has been shown that rapid evolution in mitochondrially encoded subunits can indeed be associated with rapid divergence in interacting subunits  and that positive selection is particularly pronounced among interacting residues in ETC proteins [15, 44]. More broadly, given that some of the main phenotypic differences associated with anthropoid origins are related to aerobic energy metabolism (e.g., longer lifespan, larger neocortex, and prolonged fetal development), both structural and regulatory evolutionary change in electron transport chain genes are likely to have contributed to the emergence and evolution of anthropoid primates [8, 9, 24, 45].
We sequenced the COX5A coding region for 16 mammalian species, including eight apes: human (Homo sapiens (2X)), common chimpanzee (Pan troglodytes), bonobo (Pan paniscus), gorilla (Gorilla gorilla), orangutan (Pongo pygmaeus), red-cheeked gibbon (Nomascus gabriellae) and siamang (Symphalangus syndactylus); two Old World monkeys: mantled guereza (Colobus guereza) and olive baboon (Papio anubis); three New World monkeys: pygmy marmoset (Callithrix pygmaea), white-lipped tamarin (Saguinus labiatus) and white-eared titi monkey (Callicebus donacophilus); three strepsirrhines: slow loris (Nycticebus coucang), brown greater galago (Otolemur crassicaudatus) and brown lemur (Eulemur fulvus) and one marsupial, the parma wallaby (Macropus parma) via RACE-PCR . Four additional primate and two outgroup sequences were obtained from public databases: Philipine tarsier (Tarsius syrichta, AY_236506), common squirrel monkey (Saimiri sciureus, AY_585857), rhesus monkey (Macaca mulatta, AY_585861), human (NM_004255), mouse (Mus musculus, NM_007747), and cow (Bos Taurus, NM_00100289). Finally, 8 additional outgroup species were obtained from the ENSEMBL public database, including: frog (Xenopus tropicalis, ENSXETT00000045679), chicken (Gallus gallus, ENSGALT00000022855), gray short-tailed opossum (Monodelphis domestica, ENSMODT00000011691), African elephant (Loxodonta africana, ENSLAFT00000006266), cat (Felis catus, ENSFCAT00000010590), little brown bat (Myotis lucifugus, ENSMLUT00000013702), shrew (Sorex araneus, ENSSART00000003977) and rabbit (Oryctolagus cuniculus, ENSOCUT00000003256). Species in which there was more than one copy of COX5A, or for which poor reads were available, were not included in the study. All sequences newly obtained in this study were deposited in GenBank (DQ987236–DQ987252). Human reference sequence NM_004255 was used in the sequence analyses described below.
RNA was isolated either with the phenol-chloroform method or the RNeasy® midi kit (Qiagen, Valencia, CA). RACE PCR  was performed on these RNAs using the following primers: Pri_R1, 5' GGTATCATCAGTATTTCCAGG 3'; Pri_R2, 5' TTAAGTTGGTCTAAGTTCCTGG 3'; Pri_R3, 5' CTTATGAGGTCCTGCTTTGTC 3'; Apes_R1, 5' TTTGTCAAGGCCCAGTTCCTC 3'; Apes_R2, 5' GAGTGGAGATTCCCAGTTCATT 3'; Apes_R3, 5' TTGGTCTAAGTTCCTGGATGAC 3'; 5AF1, 5' CATGGGTCACANGAGCANGA 3'; 5AF2, 5' GAGTTTGATGCTCGCTGGGT 3'; 5AF3, 5' GCCAGAYATNGATGCYTGGGA 3'. RACE PCR conditions were: 30 cycles of denaturation, 94°C, 40 s; annealing, 57°C, 30 s; and extension 72°C, 1 min and 10 s; initial denaturation at 94°C for 2 min and a final extension at 72°C for 7 min. RACE PCR products were visualized on 1% agarose gels and products were extracted using the Qiaquick® (Qiagen, Valencia, CA) gel extraction kit. DNA sequencing reactions were performed using the Big Dye® (Applied Biosystems, Foster City, CA) cycle sequencing kit according to the manufacturer's specifications.
Phylogenetic relationships used to investigate patterns of COX5A nucleotide and amino acid sequence evolution were obtained from the literature [46, 47]. Sequences were aligned using ClustalX 1.83.1 . The PAML 3.15  package was used to investigate the signature of positive selection among specific lineages and sites in the phylogeny. First, to investigate if rate heterogeneity existed among lineages, we compared a one omega (dN/dS) model (M0), which assumes the same relative rate (nonsynonymous divided by synonymous rate) for all lineages, with the free ratio model (M1), which allows rates to vary freely among the branches. Second, to investigate if the omega ratio varied among particular branches of interest in the phylogeny, we compared two different branch models. In the first model, two omega ratios were specified, one for all placental mammals (as a total group) and another for the remaining branches in the tree (i.e., the background). In the second model, three omega ratios were specified, one for the anthropoid clade (as a total group), another for the non-anthropoid placental mammals, and another for the remaining branches in the tree (i.e., the background). Finally, because all of these models assume a homogeneous omega ratio across codons, we also applied a branch-site test of positive selection on the anthropoid clade [49, 50]. Model A (branch-site test of positive selection) assumes four classes of sites, the first two classes having omega values 0 < ω0 < 1 and ω1 = 1, assuming purifying selection and neutrality, respectively. The other two classes have the same assumption for the background branches, but allow for positive selection (i.e. ω2>1) on the foreground branches. This model was compared with the same model A, but fixing the last two site classes to 1 according to Zhang et al. . In all cases we checked for the existence of multiple local optima, running all models three times, with three different starting omega values (0.5, 1, and 2). Models were compared using the likelihood ratio test.
In addition to the previous model-based analyses, we reconstructed ancestral COX5A coding region nucleotide sequences to infer the amino acid changes that occurred among the sampled vertebrate lineages. Sequences were reconstructed, translated, and compared by three different methods: a maximum parsimony framework using ACCTRAN and DELTRAN algorithms as implemented in PAUP* , and the codon substitution model  implemented in PAML 3.15 . Finally, to identify potential interactants with the COX5Ap amino acid replacements that occurred during anthropoid evolution, coding region nucleotide sequences were reconstructed, translated and compared for COX2p and COX4p (i.e., the genes encoding COX subunits in closest proximity to COX5Ap) using a maximum parsimony framework (ACCTRAN and DELTRAN). Ancestral reconstruction of COX4p sequences were based on analyses of sequences from Wildman et al. . Ancestral reconstruction of COX2p sequences were based on analyses of sequences listed in Additional file 1. Proximity of potentially interacting residues in COX2p and COX4p was determined based on the crystal structure of cytochrome c oxidase 2oCC, using Swiss-PDB viewer to identify the replacements occurring at a distance of 10 Å or less.
Real time PCR
To examine and potentially validate the pattern of COX5A upregulation in humans reported in Uddin et al. , a SYBR green-based quantitative real-time quantitative PCR (qRT-PCR) strategy was designed to test the same individuals and species originally investigated by the microarray experiments: Homo sapiens (N = 3), Pan troglodytes (N = 1), Gorilla gorilla (N = 1) and Macaca mulatta (N = 3). cDNA was synthesized using total RNA (50 ng) obtained from the anterior cingulate cortex of each individual using the Stratascript® First-Strand Synthesis System from Stratagene (La Jolla, CA) by following manufacturer's protocols. A serial dilution of reference cDNA was also amplified for use in standard curve construction and as a calibrator for subsequent real-time experiments using Stratagene's qRT-PCR Human Reference Total RNA (100 ng). COX5A-specific primers were designed in regions that were 100% conserved among the species and individuals hybridized to the microarray: COX5AF2 (5'-ATCCAGTCAGTTCGCTGCTA-3') and COX5AR2 (5'GTTTATCCCTTTACGCAATTCC-3') amplified a 123-bp product. COX5A expression levels were scaled to that of EIF3S7, a control gene on the Affymetrix HG-U133A and HG-U133B microarray chips that demonstrated one of the lowest standard deviations in expression levels among all tested samples (data not shown). Primers were designed in regions that were 100% conserved among species with available genomic data: EIF3F1 (5'-AATGTGTTTGCCACTGATGC-3') and EIF3R1 (5'AGGAGGTCAAAGTCAGAGTTGTC-3') amplified a 137-bp product. For both primer sets, one primer was designed to fall in two exons in order to reduce the possibility of amplifying products from potentially contaminating genomic DNA. All primers were HPLC purified, and optimal concentrations were established using serial dilutions of reference cDNA in preliminary experiments.
Standard curves for both primer sets produced efficiencies > 91% and Rsq > 0.99, thus meeting or exceeding the manufacturer's recommended values for ensuring a robust qRT-PCR assay. Quantitative RT-PCR reactions were run on Stratagene's Mx3000P instrument in triplicate for each and primer set on each individual and on each no template control (NTC) using the FullVelocity® SYBR® Green QPCR Master Mix® (Stratagene) following manufacturer's protocols and including both the optional diluted reference dye and 0.25 μl of AmpErase® Uracil N-glycosylase from Applied Biosystems (Foster City, CA). After ensuring that all NTCs were negative and that all samples fell within the linear range of amplification as previously determined by the standard curves, relative COX5A expression levels were calculated using the 2-ΔΔC T method described in Livak and Schmittgen  for target and reference samples, amplified in separate wells.
The localization of COX5Ap was examined in neocortex samples from non-geriatric adult macaque monkeys (Macaca maura), gorillas, common chimpanzees, and humans (N = 2 individuals per species). Macaque monkey brains were obtained from animals transcardially perfused with 4% paraformaldehyde as part of an unrelated study. Brains of gorillas, chimpanzees, and humans were collected within 14 hours of death and immersed in 10% formalin. Tissue sections were cut at a thickness of 40 μm with a freezing microtome.
Immunohistochemistry was carried out on sections from the dorsolateral prefrontal cortex. Initial single-label immunohistochemical staining was performed using two different antibodies raised against the human COX5Ap, a mouse monoclonal IgG antibody (A-21363; Molecular Probes; dilution 1:200) and a rabbit polyclonal IgG antibody (11448-1-AP; Proteintech Group, Inc.; dilution 1:50). Prior to immunostaining, sections were pretreated for antigen retrieval by incubation in 10 mM sodium citrate buffer (pH 3.5) at 37°C in an oven for 30 minutes. Sections were then incubated in the primary antibody diluted in PBS with 2% normal serum and 0.1% Triton X-100 detergent for approximately 48 hours on a rotator at 4°C. After rinsing in PBS, sections were incubated in a 1:200 dilution of Alexa Fluor 488-conjugated anti-mouse or anti-rabbit secondary antibody. Sudan Black B (1% in 70% ethanol) was used to quench the autofluorescence generated by lipofuscin pigments.
To characterize further the cellular localization of COX5Ap, we also performed double-labeling immunofluorescence experiments in the perfusion-fixed macaque monkey samples using the polyclonal COX5Ap antibody in combination with mouse monoclonal antibodies against (1) microtubule-associated protein 2 (MAP2) (MAB3418, clone AP20; Chemicon International; dilution 1:200), (2) neuron-specific nuclear protein (NeuN) (MAB377; Chemicon International; dilution 1:100), and (3) glial fibrillary acidic protein (GFAP) (MU020-UC; BioGenex Laboratories, Inc.; dilution 1:10,000). Both primary antibodies were incubated with the tissue simultaneously for 48 hours as described above. Immunoreactivity was revealed using an Alexa Fluor 488-conjugated anti-rabbit secondary antibody to visualize COX5Ap and an Alexa Fluor 568-conjugated anti-mouse secondary antibody to visualize MAP2, NeuN, and GFAP. In all immunohistochemistry runs, specificity of the reaction was confirmed by processing negative control sections excluding the primary antibody. No immunostaining was observed in control sections.
Brain sections were imaged with a BioRad MRC 1024 confocal laser scanning system coupled to an Olympus IX-70 microscope. Images were acquired with a 40× objective lens, a slice thickness of 1.5 μm, and a z step of 0.5 μm. Figures show a z projection of three contiguous confocal slices.
Quantification of the percentage of COX5Ap-immunoreactive cells that also contained NeuN in macaques (n = 2) was performed using the optical disector method as described previously  implemented in StereoInvestigator software (MBF Bioscience, Williston, VT). In two sections for each monkey, optical disector frames (30 μm × 30 μm × 6 μm) were placed within a contour drawn around the entire cortical width in the dorsolateral prefrontal cortex (Brodmann's area 9). Optical disectors were placed within this contour in a systematic random fashion using the fractionator method. Counting frames were investigated with a 63× objective (Zeiss Plan-Apochromat, N.A. 1.4) and cells were marked if their nucleolus was contained within the three-dimensional limits of the counting frame. Our estimate of the percentage of COX5A+NeuN-immunoreactive cells is based on a total sample of 619 cells.
This work was supported by NIH grant RO1 DK56927, NSF grants BCS0318375, BCS0550209 BCS0515484, and BCS0549117, the Wenner-Gren Foundation for Anthropological Research, and the James S. McDonnell Foundation (22002078). The authors thank Ms. Jennifer Leith and Cheryl D. Stimpson for laboratory assistance, Dr. Maik Hüttemann for useful discussions and Dr. A. Popratiloff for assistance with confocal microscope imaging. For primate samples we thank Dr. Caro-Beth Stewart (SUNY, Albany), the Center for Reproduction of Endangered Species at the San Diego Zoological Society, Duke University Primate Center, Southwest National Primate Research Center, and Coriell Institute for Medical Research. The brain samples used in this study were loaned by the Great Ape Aging Project (USPHS/NIH grant AG14308, "A Comparative Neurobiology of Aging Resource," J. Erwin, PI), the Foundation for Comparative and Conservation Biology, and the Northwestern University Alzheimer's Disease Center Brain Bank (NADC grant P30 AG13854).
- Adkins RM, Honeycutt RL: Evolution of the primate cytochrome c oxidase subunit II gene. J Mol Evol. 1994, 38 (3): 215-231. 10.1007/BF00176084.View ArticlePubMedGoogle Scholar
- Adkins RM, Honeycutt RL, Disotell TR: Evolution of eutherian cytochrome c oxidase subunit II: heterogeneous rates of protein evolution and altered interaction with cytochrome c. Molecular biology and evolution. 1996, 13 (10): 1393-1404.View ArticlePubMedGoogle Scholar
- Andrews TD, Easteal S: Evolutionary rate acceleration of cytochrome c oxidase subunit I in simian primates. J Mol Evol. 2000, 50 (6): 562-568.PubMedGoogle Scholar
- Andrews TD, Jermiin LS, Easteal S: Accelerated evolution of cytochrome b in simian primates: adaptive evolution in concert with other mitochondrial proteins?. J Mol Evol. 1998, 47 (3): 249-257. 10.1007/PL00006382.View ArticlePubMedGoogle Scholar
- Baba ML, Darga LL, Goodman M, Czelusniak J: Evolution of cytochrome C investigated by the maximum parsimony method. J Mol Evol. 1981, 17 (4): 197-213. 10.1007/BF01732758.View ArticlePubMedGoogle Scholar
- Doan JW, Schmidt TR, Wildman DE, Uddin M, Goldberg A, Huttemann M, Goodman M, Weiss ML, Grossman LI: Coadaptive evolution in cytochrome c oxidase: 9 of 13 subunits show accelerated rates of nonsynonymous substitution in anthropoid primates. Mol Phylogenet Evol. 2004, 33 (3): 944-950. 10.1016/j.ympev.2004.07.016.View ArticlePubMedGoogle Scholar
- Goldberg A, Wildman DE, Schmidt TR, Huttemann M, Goodman M, Weiss ML, Grossman LI: Adaptive evolution of cytochrome c oxidase subunit VIII in anthropoid primates. Proc Natl Acad Sci USA. 2003, 100 (10): 5873-5878. 10.1073/pnas.0931463100.PubMed CentralView ArticlePubMedGoogle Scholar
- Grossman LI, Schmidt TR, Wildman DE, Goodman M: Molecular evolution of aerobic energy metabolism in primates. Mol Phylogenet Evol. 2001, 18 (1): 26-36. 10.1006/mpev.2000.0890.View ArticlePubMedGoogle Scholar
- Grossman LI, Wildman DE, Schmidt TR, Goodman M: Accelerated evolution of the electron transport chain in anthropoid primates. Trends Genet. 2004, 20 (11): 578-585. 10.1016/j.tig.2004.09.002.View ArticlePubMedGoogle Scholar
- Mishmar D, Ruiz-Pesini E, Mondragon-Palomino M, Procaccio V, Gaut B, Wallace DC: Adaptive selection of mitochondrial complex I subunits during primate radiation. Gene. 2006, 378: 11-18. 10.1016/j.gene.2006.03.015.View ArticlePubMedGoogle Scholar
- Osada N, Kusuda J, Hirata M, Tanuma R, Hida M, Sugano S, Hirai M, Hashimoto K: Search for genes positively selected during primate evolution by 5'-end-sequence screening of cynomolgus monkey cDNAs. Genomics. 2002, 79 (5): 657-662. 10.1006/geno.2002.6753.View ArticlePubMedGoogle Scholar
- Schmidt TR, Goodman M, Grossman LI: Molecular evolution of the COX7A gene family in primates. Molecular biology and evolution. 1999, 16 (5): 619-626.View ArticlePubMedGoogle Scholar
- Schmidt TR, Goodman M, Grossman LI: Amino acid replacement is rapid in primates for the mature polypeptides of COX subunits, but not for their targeting presequences. Gene. 2002, 286 (1): 13-19. 10.1016/S0378-1119(01)00800-9.View ArticlePubMedGoogle Scholar
- Schmidt TR, Jaradat SA, Goodman M, Lomax MI, Grossman LI: Molecular evolution of cytochrome c oxidase: rate variation among subunit VIa isoforms. Molecular biology and evolution. 1997, 14 (6): 595-601.View ArticlePubMedGoogle Scholar
- Schmidt TR, Wildman DE, Uddin M, Opazo JC, Goodman M, Grossman LI: Rapid electrostatic evolution at the binding site for cytochrome c on cytochrome c oxidase in anthropoid primates. Proc Natl Acad Sci USA. 2005, 102 (18): 6379-6384. 10.1073/pnas.0409714102.PubMed CentralView ArticlePubMedGoogle Scholar
- Wildman DE, Wu W, Goodman M, Grossman LI: Episodic positive selection in ape cytochrome c oxidase subunit IV. Molecular biology and evolution. 2002, 19 (10): 1812-1815.View ArticlePubMedGoogle Scholar
- Wu W, Schmidt TR, Goodman M, Grossman LI: Molecular evolution of cytochrome c oxidase subunit I in primates: is there coevolution between mitochondrial and nuclear genomes?. Mol Phylogenet Evol. 2000, 17 (2): 294-304. 10.1006/mpev.2000.0833.View ArticlePubMedGoogle Scholar
- Rizzuto R, Nakase H, Zeviani M, DiMauro S, Schon EA: Subunit Va of human and bovine cytochrome c oxidase is highly conserved. Gene. 1988, 69 (2): 245-256. 10.1016/0378-1119(88)90435-0.View ArticlePubMedGoogle Scholar
- Yang Z: PAML: a program package for phylogenetic analysis by maximum likelihood. Comput Appl Biosci. 1997, 13 (5): 555-556.PubMedGoogle Scholar
- Yang Z: Computational Molecular Evolution. 2006, Oxford: Oxford University PressView ArticleGoogle Scholar
- Golding GB, Dean AM: The structural basis of molecular adaptation. Mol Biol Evol. 1998, 15 (4): 355-369.View ArticlePubMedGoogle Scholar
- Goodman M: Positive selection causes purifying selection. Nature. 1982, 295: 630-10.1038/295630a0.View ArticlePubMedGoogle Scholar
- Ortlund EA, Bridgham JT, Redinbo MR, Thornton JW: Crystal structure of an ancient protein: evolution by conformational epistasis. Science. 2007, 317 (5844): 1544-1548. 10.1126/science.1142819.PubMed CentralView ArticlePubMedGoogle Scholar
- Uddin M, Wildman DE, Liu G, Xu W, Johnson RM, Hof PR, Kapatos G, Grossman LI, Goodman M: Sister grouping of chimpanzees and humans as revealed by genome-wide phylogenetic analysis of brain gene expression profiles. Proc Natl Acad Sci USA. 2004, 101 (9): 2957-2962. 10.1073/pnas.0308725100.PubMed CentralView ArticlePubMedGoogle Scholar
- Initial sequence of the chimpanzee genome and comparison with the human genome. Nature. 2005, 437 (7055): 69-87. 10.1038/nature04072.Google Scholar
- Gibbs RA, Rogers J, Katze MG, Bumgarner R, Weinstock GM, Mardis ER, Remington KA, Strausberg RL, Venter JC, Wilson RK, Batzer MA, Bustamante CD, Eichler EE, Hahn MW, Hardison RC, Makova KD, Miller W, Milosavljevic A, Palermo RE, Siepel A, Sikela JM, Attaway T, Bell S, Bernard KE, Buhay CJ, Chandrabose MN, Dao M, Davis C, Delehaunty KD, Ding Y: Evolutionary and biomedical insights from the rhesus macaque genome. Science. 2007, 316 (5822): 222-234. 10.1126/science.1139247.View ArticlePubMedGoogle Scholar
- Karaman MW, Houck ML, Chemnick LG, Nagpal S, Chawannakul D, Sudano D, Pike BL, Ho VV, Ryder OA, Hacia JG: Comparative analysis of gene-expression patterns in human and African great ape cultured fibroblasts. Genome Res. 2003, 13 (7): 1619-1630. 10.1101/gr.1289803.PubMed CentralView ArticlePubMedGoogle Scholar
- Sherwood CC, Hof PR: The evolution of neuron types amd cortical histology in apes and human. The Evolution of Primate Nervous Systems. Edited by: Preuss TM, Kaas JH. 2007, Oxford: Academic Press, 4: 355-378.View ArticleGoogle Scholar
- Hüttemann M, Kadenbach B, Grossman LI: Mammalian subunit IV isoforms of cytochrome c oxidase. Gene. 2001, 267 (1): 111-123. 10.1016/S0378-1119(01)00385-7.View ArticlePubMedGoogle Scholar
- Goglia F: Biological effects of 3,5-diiodothyronine (T(2)). Biochemistry (Mosc). 2005, 70 (2): 164-172. 10.1007/s10541-005-0097-0.View ArticleGoogle Scholar
- Horst C, Rokos H, Seitz HJ: Rapid stimulation of hepatic oxygen consumption by 3,5-di-iodo-L-thyronine. Biochem J. 1989, 261 (3): 945-950.PubMed CentralView ArticlePubMedGoogle Scholar
- Arnold S, Goglia F, Kadenbach B: 3,5-Diiodothyronine binds to subunit Va of cytochrome-c oxidase and abolishes the allosteric inhibition of respiration by ATP. Eur J Biochem. 1998, 252 (2): 325-330. 10.1046/j.1432-1327.1998.2520325.x.View ArticlePubMedGoogle Scholar
- Wrutniak-Cabello C, Casas F, Cabello G: Thyroid hormone action in mitochondria. J Mol Endocrinol. 2001, 26 (1): 67-77. 10.1677/jme.0.0260067.View ArticlePubMedGoogle Scholar
- Sheehan TE, Kumar PA, Hood DA: Tissue-specific regulation of cytochrome c oxidase subunit expression by thyroid hormone. Am J Physiol Endocrinol Metab. 2004, 286 (6): E968-974. 10.1152/ajpendo.00478.2003.View ArticlePubMedGoogle Scholar
- de Escobar GM, Obregon MJ, del Rey FE: Maternal thyroid hormones early in pregnancy and fetal brain development. Best Pract Res Clin Endocrinol Metab. 2004, 18 (2): 225-248. 10.1016/j.beem.2004.03.012.View ArticlePubMedGoogle Scholar
- Kester MH, Martinez de Mena R, Obregon MJ, Marinkovic D, Howatson A, Visser TJ, Hume R, Morreale de Escobar G: Iodothyronine levels in the human developing brain: major regulatory roles of iodothyronine deiodinases in different areas. J Clin Endocrinol Metab. 2004, 89 (7): 3117-3128. 10.1210/jc.2003-031832.View ArticlePubMedGoogle Scholar
- Morreale de Escobar G, Obregon MJ, Escobar del Rey F: Role of thyroid hormone during early brain development. Eur J Endocrinol. 2004, 151 (Suppl 3): U25-37. 10.1530/eje.0.151U025.View ArticlePubMedGoogle Scholar
- Gagneux P, Amess B, Diaz S, Moore S, Patel T, Dillmann W, Parekh R, Varki A: Proteomic comparison of human and great ape blood plasma reveals conserved glycosylation and differences in thyroid hormone metabolism. Am J Phys Anthropol. 2001, 115 (2): 99-109. 10.1002/ajpa.1061.View ArticlePubMedGoogle Scholar
- Sherwood CC, Stimpson CD, Raghanti MA, Wildman DE, Uddin M, Grossman LI, Goodman M, Redmond JC, Bonar CJ, Erwin JM, Hof PR: Evolution of increased glia-neuron ratios in the human frontal cortex. Proc Natl Acad Sci USA. 2006Google Scholar
- Popadin K, Polishchuk LV, Mamirova L, Knorre D, Gunbin K: Accumulation of slightly deleterious mutations in mitochondrial protein-coding genes of large versus small mammals. Proc Natl Acad Sci USA. 2007, 104 (33): 13390-13395. 10.1073/pnas.0701256104.PubMed CentralView ArticlePubMedGoogle Scholar
- Ohta T: Synonymous and nonsynonymous substitutions in mammalian genes and the nearly neutral theory. J Mol Evol. 1995, 40 (1): 56-63. 10.1007/BF00166595.View ArticlePubMedGoogle Scholar
- Schmitz J, Ohme M, Zischler H: The complete mitochondrial sequence of Tarsius bancanus: evidence for an extensive nucleotide compositional plasticity of primate mitochondrial DNA. Mol Biol Evol. 2002, 19 (4): 544-553.View ArticlePubMedGoogle Scholar
- Willett CS, Burton RS: Evolution of interacting proteins in the mitochondrial electron transport system in a marine copepod. Molecular biology and evolution. 2004, 21 (3): 443-453. 10.1093/molbev/msh031.View ArticlePubMedGoogle Scholar
- Schmidt TR, Wu W, Goodman M, Grossman LI: Evolution of nuclear- and mitochondrial-encoded subunit interaction in cytochrome c oxidase. Mol Biol Evol. 2001, 18 (4): 563-569.View ArticlePubMedGoogle Scholar
- Caceres M, Lachuer J, Zapala MA, Redmond JC, Kudo L, Geschwind DH, Lockhart DJ, Preuss TM, Barlow C: Elevated gene expression levels distinguish human from non-human primate brains. Proc Natl Acad Sci USA. 2003, 100 (22): 13030-13035. 10.1073/pnas.2135499100.PubMed CentralView ArticlePubMedGoogle Scholar
- Goodman M, Porter CA, Czelusniak J, Page SL, Schneider H, Shoshani J, Gunnell G, Groves CP: Toward a phylogenetic classification of Primates based on DNA evidence complemented by fossil evidence. Mol Phylogenet Evol. 1998, 9 (3): 585-598. 10.1006/mpev.1998.0495.View ArticlePubMedGoogle Scholar
- Murphy WJ, Eizirik E, O'Brien SJ, Madsen O, Scally M, Douady CJ, Teeling E, Ryder OA, Stanhope MJ, de Jong WW, Springer MS: Resolution of the early placental mammal radiation using Bayesian phylogenetics. Science. 2001, 294 (5550): 2348-2351. 10.1126/science.1067179.View ArticlePubMedGoogle Scholar
- Thompson JD, Gibson TJ, Plewniak F, Jeanmougin F, Higgins DG: The CLUSTAL_X windows interface: flexible strategies for multiple sequence alignment aided by quality analysis tools. Nucleic Acids Res. 1997, 25 (24): 4876-4882. 10.1093/nar/25.24.4876.PubMed CentralView ArticlePubMedGoogle Scholar
- Yang Z, Nielsen R: Codon-substitution models for detecting molecular adaptation at individual sites along specific lineages. Mol Biol Evol. 2002, 19 (6): 908-917.View ArticlePubMedGoogle Scholar
- Zhang J, Nielsen R, Yang Z: Evaluation of an improved branch-site likelihood method for detecting positive selection at the molecular level. Molecular biology and evolution. 2005, 22 (12): 2472-2479. 10.1093/molbev/msi237.View ArticlePubMedGoogle Scholar
- Swofford D: PAUP* phylogenetic analysis using parsimony (*and other methods). 4.0b10. 2002, Sunderland, MA: Sinauer AssociatesGoogle Scholar
- Goldman N, Yang Z: A codon-based model of nucleotide substitution for protein-coding DNA sequences. Mol Biol Evol. 1994, 11 (5): 725-736.PubMedGoogle Scholar
- Livak KJ, Schmittgen TD: Analysis of relative gene expression data using real-time quantitative PCR and the 2(-Delta Delta C(T)) Method. Methods. 2001, 25 (4): 402-408. 10.1006/meth.2001.1262.View ArticlePubMedGoogle Scholar
This article is published under license to BioMed Central Ltd. This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.